System and methods of tissue microablation using fractional treatment patterns

ABSTRACT

An apparatus for treating tissue includes a first energy application device to direct energy at tissue of a patient to cause at least one channel to be formed and a controller to control application of energy from the first energy application device to form the at least one channel. The at least one channel may be in the shape of a spiral-like shape or may be in a flower-like shape. Mechanisms are provided to help open channels formed in the human skin structure. A second energy application source may be used to maintain the channel open after formation. The controller may cause the first energy application device to form a plurality of channels of varying depth, width and distribution over the human skin surface. The apparatus to control the application of energy may be operated using a foot-activated pedal.

RELATED APPLICATIONS

This application is a continuation application of U.S. application Ser.No. 13/038,773, filed Mar. 2, 2011, which relates to and claims priorityto: U.S. Application No. 61/310,239, filed on Mar. 3, 2010, entitled“Apparatus and Method for Microablation of Tissue and For MaintainingFormed Microchannels Open”; U.S. Application No. 61/310,249, filed onMar. 3, 2010, entitled “System and Method of Laser Microablation ofTissue”; U.S. Application No. 61/310,254, filed on Mar. 3, 2010,entitled “Methods of Microablation of Tissue and MicroablatingPatterns”; U.S. Application No. 61/310,256, filed on Mar. 3, 2010,entitled “Footswitch for Activation and Dynamic Control of Light-BasedMicroablation System or Device and Tissue Ablation Parameters”, and U.S.Application No. 61/439,056, filed on Feb. 3, 2011, entitled “System andMethods of Tissue Microablation Using Fractional Treatment Patterns”,the entireties of which are incorporated by reference herein.

FIELD OF THE INVENTION

A system and methods of laser microablation provide selection andcontrol of the distribution, densities and patterns of treatment “spots”and resulting macro-spots and microchannels created in human tissue fortreatment of various skin and tissue conditions and pathologies.

The invention also provides a method of microablating tissue with apattern of microchannels in which certain microchannels define a givendepth and diameter to achieve a particular purpose. More particularly,the method forms superficial microchannels to help to provide mechanicalsupport to and to prevent flow of fluids into, and out of, proximatedeep microchannels. The method of the invention also helps deepmicrochannels retain an open structure during tissue treatment.

The present disclosure also relates to an apparatus and method forcreating microablated channels in skin and for maintaining suchmicroablated channels, once formed, open. The present disclosure isfurther directed to treating subsurface tissue through the channelscreated.

A system and method of laser microablation is disclosed which alsoprovides selection and control of the distribution, densities, andactual impact of microchannels or treatment “spots” created insubsurface tissue that permits customized impacts, including forinstance ablation-coagulation ratio, with respect to treatment type,tissues targeted, and skin and tissue characteristics and pathologies.

The invention also discloses and provides a mode of control, e.g.,active, employing a foot activated control device for integration with alight-based ablation system or device that provides operator selectionand control of modes of operation of the system or device, and selectionand dynamic control of ablation treatment parameters.

BACKGROUND

Prior art laser systems are configured to produce sufficient energy toreach tissue ablation thresholds having fluence levels of about 5 J/cm²,and to create a variety of treatment spot sizes on the order of fromabout 120 um to about 2 mm. Such laser systems are powerful, producinghigh peak-power of up to about 280 W and up to about 222 mJ/pulse. Inaddition, these laser systems can deliver a range of ablative fractionaltreatment patterns with high-energy, short pulse scanning to form small,deep microablative treatment spots and large, superficial treatmentspots, and combinations of both spot types. However, single lasersystems with low power, capable of producing peak-power of up to about40 W, and a limited range of working parameters may reach tissueablation thresholds with only a certain maximum spot size above whichtissue ablation cannot be achieved. Where treatment conditions orpathologies warrant scanning large areas of tissue, such single lasersystems are inefficient and not effective. Thus, it is desirable for alow-power laser system and corresponding methods of ablative fractionaltreatment to produce fractional macro-spots that are comparativelylarger than a maximum single laser spot size and can effectively ablatetissue for the apparatus described with reference to the description ofthe embodiments of FIG. 3 to FIG. 12B herein. Otherwise, the inventionsof the present application are applicable to both lower power and highpower devices. It is also desirable to provide a laser system andcorresponding fractional treatment methods that produce macro-spotscomprising impacts of micro-spots and micro-lines, while maintainingintact tissue between micro-spots and micro-lines, to therebyeffectively create a fractional pattern within a fractional pattern.

SUMMARY OF THE INVENTION

In one aspect, an apparatus for treating tissue is disclosed. Theapparatus includes a first energy application device to direct energy attissue of a patient to cause at least one channel to be formed; a secondenergy application device to direct energy at the tissue of the patientto prevent the at least one channel from substantially closing; and acontroller to: control application of energy from the first energyapplication device to form the at least one channel, and controlapplication of energy from the second energy application device to theat least one channel to prevent the at least one channel fromsubstantially closing for at least a pre-determined interval of time.The first and the second energy application devices may include the samedevices.

In another aspect, the second energy application device includes a fluidsource; and a pump to pressure fluid from the fluid source towards theat least one channel.

Further, the pump is configured to: create a vacuum external to the atleast one channel to remove at least some of the fluid directed into theat least one channel.

Further, the fluid of the fluid source includes one or more of: gas,enhancing fluid to enhance the effect of laser energy transmittedthrough the pressurized enhancing fluid, and medicinal fluid.

In yet another aspect, the second energy application device includes acontrollable ultrasound device to apply ultrasound energy in a directionsubstantially parallel to a longitudinal axis of the at least onechannel to generate standing waves of varying amplitude to cause varyingelasticity levels of the tissue.

The second energy application device may include a controllable energyapplication device to generate one or more standing waves over the atleast one channel to elevate the Young modulus of the tissue.

The at least one channel may include a plurality of channels, and thecontrollable energy application device to generate the one or morestanding waves may include a controllable energy application device togenerate one or more standing waves having wavelengths based on adistance between at least two of the plurality of channels.

The second energy application device may also include a controllableultrasound device to apply ultrasound energy in a direction along thetissue of a patient perpendicular to a longitudinal axis of the at leastone channel to elevate the effective Young Modules of the tissue of thepatient.

In another aspect, the apparatus for treating tissue includes a firstenergy application device to direct energy at a selected tissue surfaceof a patient to cause at least one channel to be formed; a controllerto: control one or more parameters of application of energy from thefirst energy application device to form, and the controller furthercausing the first energy application device to form more than onechannel on the selected skin surface of a patient, the distribution ofthe more than one channel being non-uniform over the skin surface.

The more than one channel formed may vary in depth of penetration intothe skin surface of the human.

The time rate of the first energy application device forming the morethan one channel may be determined by the rate of travel of the firstenergy application device over the skin surface.

Further, the controller is operatively connected to one of a manually ora foot operated device to control the application of the first energyapplication device. The controller may include a manual or foot operateddevice to apply energy to the selected tissue with a selected randomlydetermined density.

In another aspect, a sensor on the first energy application device maybe connected to the controller and senses the rate of travel of thefirst energy application device and signals the controller to cause thefirst energy application device to form the more than one channel.

In another aspect, the channels formed may all be of one depth into theskin surface, or are of varying depth into the skin surface. The depthmay be controlled by the controller in response to sensing the positionof the first energy application device on the skin surface by a sensordevice in the first energy application device.

Further, the density of the more than one channel on the skin surfacemay be controlled by the controller in response to sensing the positionof the first energy application devices on the skin surface by a sensordevice operatively associated within the first energy applicationdevice.

In another embodiment, an apparatus for treating tissue, may include afirst energy application device to direct energy at tissue of a patientto cause at least one channel to be formed; a controller to: controlapplication of energy from the first energy application device to formthe at least one channel, and the controller may control the applicationof energy in response to the activation of a foot-operated deviceoperatively connected to the controller.

Further, the foot-operated device may include foot-activateable devicesto control one or more of the parameters: time intervals betweenactivation of the first energy application device; the amount of energydelivered to the first energy activation devices; the depth of thechannels formed; the distribution of the channels formed on the skinsurface; and the width of the channels formed.

Each of the foregoing parameters may be controlled by a separate sensordevice mounted on the foot-operated device and at least one of thesensors controlling the parameters may be variably activateable.

In yet another embodiment, an apparatus for treating tissue, may includea first energy application device to direct energy at tissue of apatient to cause at least one channel to be formed; a controller to:control application of energy from the first energy application deviceto form the at least one channel, the controller applying energy fromthe first energy application device to form a central channel; and thecontroller further applying energy from the first energy applicationdevice to form one or more secondary channels in the vicinity of thecenter channel.

The one or more secondary channels may be spaced a predetermineddistance from the central channel.

The one or more secondary channels may substantially abut the centralchannel periphery.

The one or more secondary channels may be arranged in any configurationand substantially surround the central channel.

The central channel may be of depth X and the one or more secondarychannels are of depth A<X.

The diameter of the central channel and the one or more secondarychannels may be of substantially the same diameter.

The diameter of the central channel may be X and the diameter of the oneor more secondary channels is x>X.

In yet a further embodiment, an apparatus for treating tissue mayinclude a first energy application device to direct energy at a tissuesurface of a patient to cause at least one channel to be formed; acontroller to: control application of energy from the first energyapplication device to form the at least one channel, and the controllerforming the at least one channel in the shape of a decreasing spiral.

One or more of: depth of the channel, width of the channel, and distancebetween adjacent channels may be controlled by the controller.

More than one decreasing spiral may be formed on the skin of a patientwithin a predetermined skin area.

The controller may cause the first energy application device to form atleast one micro-spot within the decreasing spiral channel.

The controller may cause the first energy application device to form atleast one micro-spot outside of the at least one channel.

The decreasing spiral may be formed in at least one of the followingshapes: triangular; rectangular; square; and hexagonal.

Further, the controller may cause the first energy application device toproduce at least one channel having an area of ablation, followed by anarea of coagulation followed by an area of thermal heating.

The first energy application device may be one of a CO₂, an Er:YAG, anNd:YAG; an Er:GHss Ulium laser operating in one of a continuous wavemode and a pulsed mode.

The depth of the channel may be varied by the controller along thedecreasing spiral formed by the first energy application device.

Details of one or more implementations are set forth in the accompanyingdrawings and in the description below. Further features, aspects, andadvantages will become apparent from the description, the drawings, andthe claims.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic illustration of a microablation system accordingto one aspect of the invention, and a schematic illustration of atreatment spot or microchannel created in tissue as a result ofmicroablation produced with the system;

FIG. 2 is a cross-sectional illustration of different types ofmicrochannels created with laser microablation techniques according tothe invention;

FIGS. 3A and 3B are illustrations of fractional patterns of treatmentmacro-spots having a snail-shaped pattern according to another aspect ofthe invention;

FIGS. 3C and 3D are illustrations of fractional patterns of micro-spotswith a treatment macro-spot;

FIG. 4 is an illustration of a fractional pattern of treatment spotscreated by impact of a single beam;

FIG. 5A is an illustration of a fractional pattern of a treatmentmacro-spot according to the invention;

FIG. 5B is an illustration of energy distribution along a cross sectionof the treatment macro-spot shown in FIG. 5A;

FIG. 6A is an illustration of a fractional pattern of a treatmentmacro-spot according to the invention;

FIG. 6B is an illustration of energy distribution along a cross sectionof the treatment macro-spot shown in FIG. 6A;

FIG. 7A is an illustration of a fractional pattern of a treatmentmacro-spot according to the invention;

FIG. 7B is an illustration of energy distribution along a cross sectionof the treatment macro-spot shown in FIG. 7B;

FIGS. 8A-8D are illustrations of other fractional patterns of treatmentmacro-spots according to the invention;

FIGS. 9A and 9B are cross-sectional illustrations of microchannelsresulting in tissue from fractional patterns of macro-spots shown inFIGS. 3A and 3B;

FIG. 10 is a cross-sectional illustration of a portion of themicrochannel shown in FIG. 9B;

FIG. 11 is a cross-sectional illustration of a microchannel formed froma macro-spot having a varying distribution of energy levels and fluence;and

FIG. 12A is an illustration of a fractional pattern of a treatmentmacro-spot according to the invention;

FIG. 12B is an illustration of a microchannel formed from a macro-spothaving a varying density pattern as shown in FIG. 12A;

FIGS. 13A and 13B are illustrations of a microablation pattern ofmicrochannels defining different diameters and depths according to theinvention;

FIG. 14 is an illustration of another microablation pattern ofmicrochannels according to the invention;

FIG. 15 is a cross-sectional illustration coagulation microchannelsaccording to the invention;

FIG. 16 is a schematic diagram of an apparatus used for hole formationand for maintaining holes (channels) open;

FIGS. 17A-17B are schematic diagrams of an apparatus used for supplyingand removing pressurized fluids;

FIG. 18 is a schematic illustration of different types of patterns ofmicrochannels or treatments “spots” resulting from microablationtreatment;

FIG. 19 is a schematic illustration of varying distribution and densityof treatment spots in a given treatment area as a result ofmicroablation treatment controlled by the scanner and software accordingto the invention;

FIG. 20 is a schematic perspective illustration of a footswitchaccording to the invention for operation of a light-based tissueablation system or device; and

FIG. 21 is a schematic illustration of a user interface for use inselecting and enabling ablation parameter controls integrated with thefootswitch shown in FIG. 20.

DETAILED DESCRIPTION

The invention provides a system and methods for treating tissue usingelectromagnetic radiation and microablation techniques. Such a systemand microablation techniques form microchannels through a surface oftissue to treat subsurface tissue for any of a number of skin conditionsand pathologies. The tissue ablation system according to the inventionincludes a laser unit and a laser emitting device for ablatingmicrochannels in tissue, such as the system disclosed in assignee'sco-pending patent application Ser. No. 11/730,017, filed Mar. 29, 2007and entitled “System and Method of Microablation of Tissue” (PatentPublication No. 2008/0071258), the entirety of which is incorporatedherein by reference. The laser emitting device includes a scanningdevice configured with a number of mirrors or alternatively a singlemirror, or other reflective surfaces, disposed in an arrangement and atan orientation relative to one another such that the laser emittingdevice emits a laser beam in a given pattern of rays or beams. Softwarecontrols the scanning device to emit laser light in a desired beampattern and/or beam profile to achieve specific treatment protocols.These types of scanning devices are disclosed in assignee's U.S. Pat.Nos. 5,743,902, 5,957,915, and 6,328,733, the entireties of which areincorporated herein by reference.

Alternatively, the scanning device may be or may include a laser beamsplitter, which is constructed and arranged to deliver a given patternof treatment radiation to produce multiple treatment areas or “spots.”Such treatment “spots” create multiple microchannels in subsurfacetissue that may be distributed in a pattern substantially throughout atissue treatment area. For instance, using a laser beam splitter,ablation radiation may be varied to achieve a certain fractional patternof spots along a treatment area to create microchannels having certainparameters, such as certain depths and diameters. The beam splitter mayinclude a multi-lens plate having a plurality of lenses. Some lenses maybe configured to focus ablation radiation more than other lenses, suchthat, some lenses sufficiently focus ablation radiation to penetrate thesurface of tissue, while other lenses do not. The plurality of lensesmay include lenses having varying size and focal length. The pluralityof lenses may include a mechanism, e.g., an array of controllablefilters or shutters, which may open or close the optical path, to or of,any single lens. The multi-lens plate thereby may create any fractionalpattern of treatment macro-spots or lines that are drawn or createdusing any subset of lenses of the multi-lens plate. The invention is notlimited to scanning laser beam splitters and envisions that othersophisticated stationary beam splitters may achieve the scanningfunction disclosed herein. For purposes of disclosing the invention, theterm “scanner” or “scanning device” is used to refer to a scanningdevice in the laser emitting device as described with reference to FIG.1 and to laser beam splitters, whether such beam splitters arestationary or portable.

In lieu of the scanning devices described above, a semiconductor devicenamed DLP® and manufactured by Texas Instruments may be used incoordination with the laser of FIG. 1. With a laser unit 2, shown inFIG. 1, a DLP® semiconductor may be used to direct laser light to one ormore of the hinged-mounted microscopic mirrors and then onto the humanskin. DLP® is described in an article “How DLP Technology Works” and canbe found at: www.dlp.com/technology/how-dlp-works/default.aspx.

Generally, the laser emitting device and the scanning device apply alaser beam to a tissue treatment area with a given emitted beam patternsuch that treatment areas or “spots” and the resulting multiplemicrochannels are created with required or desired dimensions and aredistributed throughout subsurface tissue in a required or desiredpattern. The scanning device uses software designed and configured tochange and to control treatment spots with respect to spot pattern, spotpattern size, spot size, spot shape, spot densities, and/or spot orablated microchannel depth and pattern/sequence vs. randomized.

In one configuration according to the invention, a laser unit with alaser emitting device includes a scanning device and software to produceand emit a laser beam during scanning that creates multiple spots andmicrochannels in a randomized sequence. As the scanning device movesacross a treatment area, the scanning device applies a laser beam asrandomized treatment spots. Movement of the scanning device controls thedistribution and density of the randomized treatment spots area acrossthe treatment area. The distribution and density of the randomizedtreatment spots is also controlled by the number of repetitions ofscanning across a given treatment area and the extent of scanningoverlap in the treatment area.

In another configuration of the invention, a laser unit and a laseremitting device includes a scanning device and software to produce andemit a laser beam during scanning that creates multiple spots in apredetermined fractional pattern to thereby create microchannels along atissue treatment area.

The scanning device and software according to the invention therebyenable controlled and intuitive treatment of tissue with more or lessdistribution and density of treatment spots along specific areas of atotal treatment area. The scanning device and software thereby permitgreater flexibility and control of microablative techniques.

Referring to FIG. 1, in one aspect, the invention provides a system forperforming microscopic ablation or partial microablation of tissue toform one or more microchannels 6 through a surface of tissue to effecttreatment within subsurface tissue. For instance, in skin tissue,proteins such as collagen reside in the dermal layer of the skin.Microchannels 6 described below may be used to target and alter collagenfibers within the skin dermis as an effective treatment of, forinstance, wrinkles of the skin or cellulite. In another instance,microchannels 6 described below may be used to target and thermallytreat portions of the skin dermis to coagulation at certain depths tothereby effectively treat undesirable skin pigmentation or lesions.Alternatively, microchannels 6 may create a passage through whichtargeted tissues may be treated, and/or through which material(s) may beextracted or material(s), such as medication, may be delivered totargeted tissues. Also, microchannels 6 may create a passage throughtargeted tissues through which a second laser beam having the same ordifferent characteristics from beams forming such microchannels 6 may besupplied. In some embodiments of the invention, microchannels 6 mayproduce partial lateral denaturation of proteins, e.g., within wallsand/or along bottoms of microchannels.

The tissue ablation system 1 includes a laser unit 2 and a laseremitting device 3 for ablating one or more microchannels 6 into tissue 5for treatment. A microchannel 6 may include a hole, column, well, or thelike created by ablating tissue 5 with a laser beam 4 which the laseremitting device 3 supplies. The laser emitting device 3 includes ascanning device 30 for emitting ablation radiation in a given fractionalpattern of treatment “spots.” As used to disclose the invention,treatment “spot” refers to an ablated area created by laser radiationand/or a microchannel 6 that results from such ablation.

The laser unit 2 may further include a controller 12 programmed andconfigured to control the laser emitting device 3. The laser unit 2 mayalso include an input interface 13 capable of receiving input parametersfrom a user of the system 1. The controller 12 may provide the laseremitting device 3 with a command, via one or more signals 14 to thelaser unit 2, for applying a pulse or a series of pulses to tissue 5 fortreatment.

The system 1 illustrated in FIG. 1 is a typical configuration andarrangement of a CO₂ laser system in which a CO₂ laser is included inthe laser unit 2, and an arm or optic fiber 15 delivers a laser beam 4to the laser emitting device 3. Alternatively, the system 1 may includea YAG or Erbium laser system that includes an Erbium laser that may behoused within the scanner 30 or a hand piece. Other laser systems withthe power to form microchannels may also be utilized.

With further reference to FIG. 1, applying laser radiation to tissuewith the laser unit 2 creates one or more microchannels 6 in subsurfacetissue and may also cause tissue surrounding the microchannels 6 todissipate heat resulting from the heating and evaporating of tissue thatcreates the microchannels 6. As a result, a thermally-affected orresidual heating zone 7 may form in surrounding walls and/or bottoms ofthe microchannels 6. The residual heating zone 7 is generally indicativeof damaged tissue and tissue necrosis, or, in particular, cell death. Asused to disclose the invention, “damaged” means inducing cell death inone or more regions of the dermal tissue of interest, or stimulating therelease of cytokines, heat shock proteins, and other wound healingfactors without stimulating necrotic cell death.

In addition, treatment spots or microchannels 6 may include exclusivelyone type of microchannel 6 or a combination of different types ofmicrochannels 6. For instance, formation of a combination of differenttypes of microchannels 6 may include a first pattern of non-invasive,superficial microchannels 6 that do not have ablative effects, but onlycoagulate tissue, and a second pattern of invasive microchannels 6 thathave ablative effects. Different types of microchannels 6 may be createdin subsurface tissue using multiple lasers that apply laser radiation atdifferent wavelengths in order to achieve different types of invasiveand non-invasive, microchannels 6. Multiple lasers may be incorporatedinto a common optical axis and may share the same delivery mechanism(s).

Referring to FIG. 2 and with further reference to FIG. 1, variousmicrochannels 6A, 6B and 6C are shown that are characterized by certainparameters including, but not limited to, microchannel diameter D anddepth d. The energy and propagation characteristics of the laser beamapplied to tissue 5 help to control the diameter D and depth d of theresulting microchannels 6A, 6B and 6C. Such energy may be pulsed laseror continuous wave laser and its propagation characteristics mayinclude, but are not limited to, selected wavelength, power, and laserbeam profile. Laser beam profile characteristics may include, but arenot limited to, pulse width, pulse duration, pulse frequency, spot sizeand fluency. Further, volumes and profiles of residual heating zones 7surrounding ablated areas are due to laser beam characteristicsincluding, but not limited to, selected wavelength, individual pulseenergy and fluence, energy of defined sequences of pulses, pulseduration, power distribution, and laser spot shape and size.

As shown in FIG. 2, microchannels 6A, 6B and 6C and residual heatingzones 7 may vary within a single treatment session, such that, more thanone type of treatment may be applied to a given tissue treatment area.For instance, a given laser beam profile may produce superficialtreatment spots and microchannels 6B, or may produce deep, more invasivetreatment spots and microchannels 6A. Another given laser beam profilemay produce superficial and comparatively large, e.g., about 1.3 mm,macro treatment spots that create superficial and relatively widemicrochannels 6C. Superficial microchannels 6B and 6C typically targetcomparatively superficial conditions and pathologies including, forinstance, skin pigmentations, pigmented lesions and the like, whilecomparatively deep microchannels 6A typically target tissue collagen andstimulate cell growth. Combining deep and superficial treatment spotsthat vary with respect to spot size (diameter), spot depth, spot shape,spot density, and/or fractional pattern enables a more dynamic treatmentprotocol than may be achieved with a single type of microablativetreatment.

Further, microchannels 6A, 6B and 6C may be created by applying laserradiation according to a random scanning sequence. Random scanningsequences may be achieved with software algorithms that configuresequential laser pulses, such that, one or more adjacent or subsequentlaser pulses may be applied at a spot farthest from the spot of a priorlaser pulse to define a predetermined fractional pattern of treatmentspots. Sequencing of adjacent or sequential laser pulses helps allowtreated tissue to cool between laser pulses.

As mentioned, the laser system 1 and/or laser unit 2 may employ softwareto configure laser beam profiles to deliver radiation to treatment areasin predetermined fractional spot patterns to create microchannels havingspecific parameters, as described above, to treat particular skinconditions and pathologies.

Macro-Spots and Microchannels

Referring to FIGS. 3A and 3B, in another aspect, the invention providesa method of tissue microablation that may employ the system 1 and/orlaser unit 2 described above with reference to FIGS. 1 and 2 including aCO₂ laser to scan tissue treatment areas with ablative radiation tocreate comparatively large treatment spots or “macro-spots.” Suchmacro-spots create shallow and relatively wide microchannels havingconfigurations that are advantageous for scanning large tissue treatmentareas. In this configuration of the system 1 and/or the laser unit 2,the CO₂ laser generates laser beams having an energy distribution orintensity approximating a particular beam profile to create apredetermined multiple macro-spots 42 and 44 within a given tissuetreatment area 40. As shown in FIGS. 3A and 3B, a single macro-spot 42and 44 results from scanning a CO₂ laser beam on a focal plane along thetreatment area 40 in a circular or spiral scan pattern to create or drawa macro-spot 42 and 44 with a spiral- or coil-shaped pattern, referredto in this disclosure as a “snail-shaped” pattern.

In a preferred embodiment of the invention, the CO₂ laser includes abeam diameter of about 120 um and operates in a continuous wave mode,irradiating a continuous scan line in a circular or spiral pattern tocreate or draw the snail-shaped pattern of the macro treatment spots 42and 44. Referring to FIG. 4 and with further reference to FIGS. 3A and3B, macro-spots 42 and 44 are large treatment spots relative to themicro treatment spots 46 shown in FIG. 4 and the microchannels 6A, 6B,and 6C shown in FIG. 2. Such micro-spots and corresponding microchannelsresult from scanning treatment areas with a laser in a pulsed mode thatcreates, with single or multiple pulses, single micro-spots and producesarrays of separate microchannels having potentially any of the generalconfigurations illustrated in FIG. 2. The 120 um CO₂ laser may scanmacro-spots 42 and 44 according to the invention with diameters of fromabout 200 um to about 2 mm, and preferably from about 700 um to about1.4 mm. The system 1 and/or the laser unit 2 according to the inventionmay be configured to readily and quickly switch between a pulsed modeand a continuous mode of operation. Therefore, while drawing anycontinuous scan lines to create macro-spots, the system 1 and/or thelaser unit 2 according to the invention can create any pattern ofseparate micro-spots 36 with any microchannel characteristics along thescan lines, as shown in FIG. 3C, or between the scan lines and/orbetween the macro-spots 42 and 44, as shown in FIG. 3D.

Referring to FIGS. 5A and 5B and with further reference to FIGS. 3A and3B, where the method according to the invention operates the CO₂ laserin continuous wave mode, the characteristics of the laser beam profileapplied to treatment areas to scan macro-spots 42 and 44 may becontrolled and varied before and/or during scanning to affect the energylevels and fluence applied along the spiral scan line that creates thesnail-shaped macro-spot 42 and 44. Applying a particular beam profile ina continuous wave mode along the scan line can thereby result inrelatively continuous or varying energy levels and fluence throughoutthe snail-shaped pattern. As a result of the controlled distribution ofenergy levels and fluence throughout the snail-shaped macro-spot 42 and44, the resulting microchannel configurations may be controlled and maybe varied depending on the treatment protocol and/or condition orpathology being treated. FIG. 5A is a top view of the snail-shapedpattern of a macro-spot 42 and 44 that illustrates higher fluence 52applied at approximately about or along a center of the treatment spot42 and 44 in comparison to fluence applied along marginal segments 53and the periphery 53 of the snail-shaped pattern. Higher fluencesegments 52 of the scan pattern would create deeper ablated portionswithin the resulting microchannel relative to those resulting from thelower fluence 53 segments. FIG. 5B illustrates an effective, cumulativeenergy distribution throughout the snail-shaped pattern along across-section of the macro-spot 42 and 44 shown in FIG. 5A taken at lineA-A′ that represents a beam profile that may have been applied to createthe macro-spot 42 and 44 and the resulting microchannel using asingle-beam, single-pulse laser or continuous laser, which may have beenused to create the macro-spot and respective microchannel.

Referring to FIGS. 6A and 6B, in contrast, other macro-spots 45 may beformed with different distributions of energy and fluence along thesnail-shaped pattern. FIG. 6A is a top view of the snail-shaped patternof a macro-spot 45 that illustrates lower fluence 54 applied atapproximately about or along a center of the treatment spot 45 incomparison to fluence applied along marginal and peripheral segments 55of the snail-shaped pattern. FIG. 6B illustrates an effective,cumulative energy distribution throughout the snail-shaped pattern alonga cross-section of the macro-spot 45 shown in FIG. 6A taken at line B-B′that represents a beam profile applied to create the macro-spot 45 andresulting microchannel.

FIGS. 7A and 7B illustrate another configuration of the snail-shapedmacro-spot 47 according to the invention created with intermittentscanning along the spiral scan line that draws the macro-spot 47 with adiscontinuous snail-shaped pattern. In one configuration of themacro-spot 47 shown in FIG. 7A, the laser energy is alternately appliedand withdrawn along the spiral scan line during continuous scanning todraw the discontinuous pattern. The intermittent applications of laserenergy may be applied along the scan line for identical durationsthroughout scanning resulting in relatively even distributions of energyalong the spiral scan line, or may be applied for varied durations suchthat segments of the scan line to which laser energy is applied arevaried in length. FIG. 7B illustrates a potential cumulative energydistribution throughout the snail-shaped pattern along a cross-sectionof the macro-spot 47 shown in FIG. 7A taken at line C-C′ that representsa beam profile.

The snail-shaped patterns of the macro-spots 42 and 44 shown in FIGS. 5Athru 7B illustrate the potential of the microablation method accordingto the invention to control and vary the energy levels and fluencethroughout the snail-shaped macro treatment spot 42 and 44 before orduring scanning to thereby create microchannels along treatment areashaving required or desired parameters and configurations that may beadvantageous toward optimizing a treatment protocol for a particularskin condition or pathology.

While the snail-shaped macro-spots 42 and 44 described above are createdwith circular spiral scanning patterns, the invention is not so limitedand envisions other spiral patterns are possible for creating the shapedmacro-spot 42 and 44. Referring to FIGS. 8A-8D, other possiblealternative scanning patterns according to the invention are illustratedthat do not include a circular spiral, but may include arectangular-shaped, triangular-shaped and other shaped spiral pattern 49as shown. Those of ordinary skill in the art will appreciate andanticipate other spiral shapes and profiles are possible to create theshaped pattern of the macro-spots.

With further reference to FIGS. 3A and 3B, the method according to theinvention may control and vary the laser beam profile and scanningmovement to create macro-spots spots 42 and 44 having a snail-shapedpattern with a given spread or density. As shown in FIG. 3A, someconfigurations of macro-spots 42 may have a snail-shaped pattern that isdense and less open, while other configurations of macro-spots 44 mayhave a snail-shaped pattern that is less dense and more open as shown inFIG. 3B. Control and variation of the spiral scanning movement of thelaser beam helps to create the snail-shaped pattern with a required ordesired spread or density, which is a direct result of the distancebetween successive snail pattern loops. In those configurations of themacro-spots 42 and 44 shown in FIGS. 3A and 3B, successive spiral loopsare formed from a given center of the spiral scan line with asubstantially consistent gradual increase in radii from the spiral scanline center to the pattern periphery, such that, distances betweensuccessive spiral loops within the pattern are substantially the same.Alternatively, successive spiral loops may be formed with graduallyincreasing or gradually decreasing radii from the spiral scan linecenter, such that, distances between successive spiral loops graduallyincrease or gradually decrease toward the pattern periphery. Inaddition, spiral loops may be formed with continuously increasing anddecreasing radii from the spiral scan line center, such that, distancesbetween spiral loops are inconsistent.

The microablative methods according to the invention, as well as thesystem 1 and/or laser unit 2 according to the invention, thereby enablecontrol and adjustment of the spread or density of the snail-shapedpattern of each macro-spot 42 and 44, as well as control and adjustmentof energy distributions and, in particular, energy levels and fluenceapplied along the spiral scan line that forms the snail-shaped pattern.The methods permit control and adjustment of these parameters prior toand/or during scanning treatments. The methods also provide flexibilityin controlling and adjusting parameters of beam profiles in ordereffective and final cumulative beam profiles are achieved that arespecific to and advantageous for treatments of particular skin andtissue conditions or pathologies.

Referring to FIGS. 9A and 9B, cross-sections of treated tissue are shownthat illustrate the macro-spot impact and the tissue effects resultingfrom fractional treatment patterns of macro-spots 42 and 44 according tothe invention. The spread or density of the snail-shaped pattern of themacro-spots 42 and 44 may be controlled to create dense or spread-outablation zones 72 and 74. In addition, the density of the snail-shapedpattern of macro-spots 42 and 44 may be further controlled to affect thehomogeneity of tissue ablation achieved within a given microchannel 62and 64. As shown in FIG. 3A, spots 42 having a dense (compared to thepattern of FIG. 3B) snail-shaped pattern create microchannels 62 with amore homogeneous spot impact. In contrast, as shown in FIG. 3B, spots 44having a less dense or more spread out snail-shaped pattern createsmicrochannels 64 with a non-homogenous spot impact.

More specifically, FIG. 9A shows the macro-spot 42 having a dense andless open snail-shaped pattern that creates a resulting microchannel 62with a substantially homogeneous impact. The spiral loops 42′ of themacro-spot 42 ablate areas of tissue 72 with a corresponding density,such that, the microchannel 62 includes a spot impact of substantiallycontiguous ablated zones 72. In contrast, FIG. 9B shows the macro-spot44 having a more open snail-shaped pattern that creates the resultingmicrochannel 64 with a non-homogeneous impact. The spiral loops 44′ ofthe macro-spot 44 ablate areas of tissue 74 with a correspondingdensity, such that, the microchannel 64 includes areas of undamagedtissue 50 between zones of ablated tissue 74. As mentioned, the spreador density of the spiral loops 42′ and 44′ of the macro-spots 42 and 44controls the spot impact that results in certain configurations of themicrochannels 62 and 64 at least in terms of homogeneity of ablation asshown here.

In addition, the spiral loops 42′ and 44′ of the snail-shaped patterns42 and 44 create, such that, one fractional pattern of impact spots orablated zones 72 and 74 is created within another fractional pattern ofmultiple microchannels 62 and 64 along a treatment area.

The macro-spots 42 and 44 shown in FIGS. 9A and 9B are presumed to havesubstantially consistent distributions of energy levels and fluencealong the scan lines forming the snail-shaped patterns, such that, theablated zones 72 and 74 within a single microchannel 62 and 64 havesubstantially similar depths and diameters. However, as described belowwith reference to FIGS. 12A and 12B, macro-spots that have varyingenergy levels and fluence along the spiral scan line forming thesnail-shaped pattern would form ablated zones within a singlemicrochannel having different depths and possibly different diameters.

As mentioned, relatively large macro-spots 42 and 44 are advantageousfor treating large areas of tissue. The resulting microchannels 62 and64 formed from the macro-spots 42 and 44 may be superficial, penetratingbelow the tissue surface to depths of from about 1 um to about 200 um,and may have the deepest points of the microchannels 62 and 63approximately about the centers of the microchannel bottoms, dependingon the energy levels and fluence applied along the spiral scan linedrawing or creating the snail-shaped pattern. The sizes of themacro-spots 42 and 44 may create microchannels 62 and 64 having widths(diameters) of from about 200 um to about 2 mm.

Referring to FIG. 10, a portion of the microchannel 64 shown in FIG. 9Billustrates the tissue effects resulting from microablative treatmentwith the macro-spot 44 patterns. The spot impact of the spiral loops ofthe macro-spot 44 are shown by the ablated zones 74, which are formedfrom heating or vaporizing tissue as a result of the energy levels andfluence applied along the spiral scan line of the snail-shaped pattern.Coagulation C zones and residual heating zones R may form within tissuesurrounding the ablated zones 74 as a result of lower energy levels andfluence received along certain depths of the subsurface tissue. Themicroablation treatment pattern thereby preferentially heats tissues atcertain required or desired depths below the tissue surface to effecttreatment, while not affecting subsurface tissue not targeted fortreatment, which remains undamaged tissue U. As described above, themacro-spot 44 having a less dense and open spiral scan line may resultin areas of undamaged tissue 50 throughout the microchannel 64, such asbetween adjacent ablated zones 74. The spread or density of the spiralscan line can thereby help to control and vary the ratio of damagedtissue to undamaged tissue within a given microchannel, such that, themacro-spot 74 can be configured to have more or less homogeneity withina microchannel.

Referring to FIG. 11, a cross-section of a microchannel 66 and spotimpact in a portion of treated tissue is illustrated. The microchannel66 has a homogeneous spot impact with contiguous ablated zones 76 and78. The ablated zones 78 oriented at substantially the center of themicrochannel 66 have greater depths than those ablated zones 76 orientedtoward the margins and periphery of the microchannel 66. The patterningof depths is illustrative of a spot impact that may result from amacro-spot 42 and 44 having higher energy levels and fluence appliedapproximately about or along the center of the snail-shaped spot patternin comparison to energy levels and fluence applied along marginalsegments and the periphery of the pattern, as is illustrated in FIG. 5A.In effect, the higher energy levels and fluence substantially about oralong the center of the macro-spot 42 and 44 destroy or vaporize tissueto greater depths along or about the center of the microchannel 66.

Referring to FIGS. 12A and 12B, a cross-section of a microchannel 68 anda spot impact in a portion of treated tissue are illustrated. Themicrochannel 68 has a non-homogeneous spot impact with undamaged tissue50 between some of the ablated zones 80. The ablated zones 80 and 82have substantially similar depths, but are either contiguous ornon-contiguous with adjacent ablated zones as a result of the density orspread of the spiral scan line that forms the snail-shaped macro-spot84. As shown in FIG. 12A, the macro-spot 84 is formed with graduallydecreasing radii from the center 86 of the spiral scan line, such that,distances between successive spiral loops gradually decrease toward themacro-spot 84 periphery. The spot impact that results includes undamagedzones 50 of tissue between ablative zones 80 along the center of themicrochannel 80 due to the larger radii and greater distances betweensuccessive spiral loops emanating from the spiral scan line center 86.The microchannel 80 also includes contiguous ablative zones 82 along themargins and periphery of the microchannel 68.

The microchannels 66 and 68 illustrated in FIG. 11 and FIG. 12B,respectively, illustrate only a few of a wide variety of possibleconfigurations of microchannels that may result from variations in thespread and density of the spiral scan line of the snail-shapedmacro-spot and from variations in the distribution of energy levels andfluence applied along the spiral scan line.

In other configurations of the microablative methods according to theinvention, and the system 1 and/or laser unit 2 according to theinvention, the CO₂ laser and the scanning device 30 may be configuredadditionally for deep fractional microablative treatments by which deepmicrochannels 6A, such as shown in FIG. 2, are created having depths anddiameters of, for instance, up to about 1000 um and 120 um,respectively. In this configuration, the CO₂ laser and emitting device 3may apply ablative radiation to treatment areas with two or more laserbeam profiles, such that, micro-spot patterns and resulting arrays ofdeep microchannels 6A are combined with macro-spot 42 and 44 patternsand resulting large, superficial microchannels 62 and 64 to form amicroablative pattern. Micro-spot and macro-spot patterns may be socombined in an unlimited manner. In addition, respective densities ofthe spot patterns may be controlled, and may be applied along treatmentareas in random, overlapping or other patterns.

Software of the system 1 and/or laser unit 2 controls and designs thelaser beam profiles by manipulating, for instance, beam power, to createarrays of single, deep microchannels 6A, 6B and 6C and patterns ofhomogeneous or non-homogeneous large, superficial microchannels 62 and64 to achieve variable ablation depths and diameters and to thereby moreprecisely control treatment of subsurface tissue. Such flexibility incombining different laser beam profiles to produce two or more types ofmicrochannels provides for customized beam profiles and therebyoptimized microablative treatment protocols for a particular conditionand pathology, as well as improved results per treatment session.

In one configuration, the method according to the invention initiallyscans a treatment area in a pulsed mode to form patterns of micro-spotswith a given spot size, e.g., 120 um, to create an array of deepmicrochannels 6A while controlling the density of the spot patterns.Secondarily the method scans the same treatment area in a continuouswave mode to form patterns of macro-spots 42 and 44 with a given spotsize, e.g., 700 um, to create a pattern of large, superficialmicrochannels 62 and 64 while controlling the density of the spotpatterns. In another embodiment, this can be done simultaneously by afast switching between pulsed mode and continuous mode so that in asingle run the laser can embed microchannels in various desiredlocations while drilling a macrochannel. The combinations of micro andmacro treatments spots, such as, for example, shown in FIGS. 3C and 3D,are unlimited and provide flexibility within in single CO₂ system interms of control and adjustment of spot size, density, energydistribution, and other parameters discussed above. Microablativetreatment patterns thereby may be readily controlled and adjusted inresponse to treatment demands.

Ablative Methods to Maintain Microchannels Open

Referring again to FIG. 1, current methods of microablation of tissue 5often experience problems associated with the ability of microchannels 6to retain their initial diameter (D) and/or depth (d) that result fromapplication of ablation radiation to the surface of tissue.Microchannels 6 have a tendency to collapse mechanically and to fillwith fluid. One solution to this problem is to freeze at least a portionof the tissue of the treatment area prior to applying ablationradiation. Freezing tissue helps tissue become relatively stiff andhelps to block the flow of fluids into the microchannels.

In one aspect, the invention provides a method of patterningmicrochannels created in a treatment area and forming microchannels withdifferent diameters and depths to achieve different functions within themicrochannels and the surrounding tissue. The patterning ofmicrochannels, and the differences between microchannels with respect todepth and diameter, help to achieve certain thermal effects and help toadvantageously shrink and dry certain microchannels and associatedsurrounding tissues.

Referring again to FIG. 2, and with further reference to FIG. 1, themethod of the invention ablates a treatment area 5 with laser radiationto create deep microchannels 6A and relatively more shallow orsuperficial microchannels 6B. The depth (d) and diameter (D) parametersof the microchannels 6A and 6B are controlled by the energycharacteristics of the applied laser radiation. The deep microchannels6A include a zone of ablation 6 having a certain depth (d) and diameter(D) and a zone of thermal damage 7 to the dermal tissue, e.g., “lethaldamage” or “sublethal damage,” resulting from the laser radiation. Therelatively more shallow or superficial microchannels 6B have a certaindepth (d) and diameter (D) to create a zone of coagulation 7 only withinwhich no ablation occurs. Rather, the zone 7 experiences tissuecoagulation that helps to shrink and to dry the superficial microchannel6B and its surrounding tissue.

The invention is not limited to laser radiation and envisions that themethod may employ coherent, non-ablative light in one or more differentmodalities, such as, for instance, a combination of treatment that mayuse one or more of RF, US, IPL or other coherent light.

Referring to FIG. 13A, and with further reference to FIG. 2, thecombination of deep and superficial microchannels 160A and 160B iscreated in the treatment area 5 in a pattern 160 whereby the deepmicrochannel 160A is surrounded by multiple superficial microchannels160B, which may be referred to as a “flower pattern,” wherein the deepmicrochannel 160A defines the flower center or stem and the multiplesuperficial microchannels 160B surround the deep microchannel 160B like“petals.” As shown in FIG. 13A, a single deep microchannel 160A issurrounded by four superficial microchannels 160B. The invention is notlimited in this respect and envisions that any number of superficialmicrochannels 160B may surround the deep microchannel 160A. In addition,the ratio of deep to superficial microchannels 160A and 160B may bevaried. Further, the invention is not limited to the pattern 160illustrated in FIG. 13A and anticipates that other configurations orpatterns of deep microchannels 160A and superficial microchannels 160Bare possible to achieve the functions of the patterning, as described infurther detail below.

As a result of ablating the treatment area 150 with the pattern 160 ofdeep and superficial microchannels 160A and 160B, the coagulationeffects resulting from ablation or formation of the superficialmicrochannels 160B help to shrink and to dehydrate the microchannel 160Band the surrounding tissue within the coagulation zone 7 of FIG. 1. Thecoagulation and drying of such surrounding tissue further helps toprevent flow of fluids into the microchannels 160A and 160B. Because ofshrinking and drying of tissue within the coagulation zone 7, thesuperficial microchannel 160B and coagulation zone 7 stiffen and therebyserve as mechanical support to the adjacent deep microchannel 160A. Themechanical support that the stiffened superficial microchannels 160B andsurrounding zones 7 lend to the deep microchannel 160A helps to preventmechanical collapse of the deep microchannel 160A. The surroundingmicrochannels 160B and coagulation zones 7 thereby help the deepmicrochannel 160A remain open and relatively dry for a sufficient periodof time after ablation to help to enable treatment and to help toenhance the effectiveness of such treatment.

Referring to FIG. 13B, a cross-sectional illustration shows amicrochannel 160C with coagulation areas or zones 7A and 7B formed alongportions of walls of the microchannel 160C. Coagulation zones 7A and 7Bmay be formed during ablation that forms the microchannel 160C in atreatment area. Application of irradiation energy configured inaccordance with one or more parameters applies to the skin or tissue ofthe treatment area and forms the microchannel 160C to an initialapproximate desired or required depth; thereafter, irradiation energyapplied to the treatment area may be altered or modified in accordancewith one or more other or different parameters, such that, as a result,irradiation energy forms coagulation zones 7A, e.g., at or proximate tothe initial approximate depth achieved, along portions of walls of themicrochannel 160C as shown in FIG. 13B. Ablation may continue byirradiating energy configured in accordance with one or more parametersto continue formation of the microchannel 160C to a subsequentapproximate depth that is relatively deeper than the initial approximatedepth achieved. Irradiation energy configured with one or more other ordifferent parameters may be applied that forms coagulation zones 7B,e.g., at or proximate to the subsequent approximate depth achieved,along portions of walls of the microchannel 160C. As shown in FIG. 13B,the coagulation zones 7A and 7B are defined at different depths of themicrochannel 160C. The coagulation zones 7A and 7B along themicrochannel 160C walls help to keep the microchannel 160C open onceformed and help to prevent or at least minimize mechanical collapse ofthe microchannel 160C, thereby helping to provide mechanical stabilityto the microchannel 160C.

Referring to FIG. 14, the pattern of microchannels shown in FIG. 13 mayinclude a pattern 161A whereby superficial microchannels 166B closelyabut or are proximate to a deep microchannel 166A.

Referring to FIG. 15, a schematic cross-sectional view illustrates analternative configuration of the microchannels 160B of FIG. 13. In theconfiguration of FIG. 15, the microchannels 170A and 170B may definerelatively shallow coagulation zones or holes that provide non-invasive,fractional treatment without creating the “microchannels” 160B of FIG.13. For instance, the depth of such coagulation zones or holes may varyfrom about zero to about one-third a depth (d1) of a corresponding deepmicrochannel 172. Creating shallow coagulation zones or holes causes thethermally-affected tissue surrounding the zones or holes to stiffen. Theshallow coagulation zones or holes also may serve as buffers orreservoirs to help collection of fluid before fluid flows into a deepmicrochannel 172.

Ultrasonic and Pressurized Systems to Maintain Open Microchannels

In another aspect, the apparatus includes a first energy applicationdevice to direct energy at tissue of a patient to cause at least onechannel to be formed, a second energy application device to directenergy at the tissue of the patient to prevent the at least one channelfrom substantially closing, and a controller to control application ofenergy from the first energy application device to form the at least onechannel, and control application of energy from the second energyapplication device to the at least one channel to prevent the at leastone channel from substantially closing for at least a pre-determinedinterval of time.

Embodiments of the apparatus may include one or more of the followingfeatures.

The second energy application device may include a controllable energyapplication device to generate one or more standing waves over the atleast one channel to elevate the Young modulus of the tissue.

The at least one channel may include a plurality of channels, and thecontrollable energy application device to generate the one or morestanding waves may include a controllable energy application device togenerate one or more standing waves having wavelengths based on adistance between at least two of the plurality of channels.

The second energy application device may include a fluid source, and apump to pump pressurized fluid from the fluid source towards the atleast one channel.

The pump may further be configured to create a vacuum external to the atleast one channel to remove at least some of the fluid that was directedinto the at least one channel.

The fluid of the fluid source may include one or more of, for example,gas, enhancing fluid to enhance the effect of laser energy transmittedthrough the pressurized enhancing fluid, and/or medicinal fluid.

The second energy application device may include a controllableultrasound device to apply ultrasound energy in a direction parallel toa longitudinal axis of the at least one channel to generate standingwaves of varying amplitude to cause varying elasticity levels of thetissue.

In another aspect, a method is disclosed. The method includes forming atleast one channel in a tissue of a patient, and applying energy to theat least one channel to prevent the at least one channel fromsubstantially closing for at least a pre-determined interval of time.

Embodiments of the method may include any one of the features describedabove in relation to the apparatus, as well as one or more of thefollowing features.

Applying the energy may include generating one or more standing wavesover the at least one channel to elevate the Young modulus of thetissue.

The at least one channel may include a plurality of channels, andgenerating the one or more standing waves may include generating one ormore standing waves having wavelengths based on a distance between atleast two of the plurality of channels.

The one or more standing waves may include troughs located approximatelyat a halfway point between the at least two of the plurality ofchannels.

Generating the one or more standing waves having wavelengths based onthe distance between at least two of the plurality of channels mayinclude generating one or more standing waves having wavelengths equalto an integer multiple, n, of the distance between the at least two ofthe plurality of channels.

Generating the one or more standing waves may include generating one ormore ultrasound standing waves.

Applying the energy may include applying ultrasound energy in adirection parallel to a longitudinal axis of the at least one channel togenerate standing waves of varying amplitude to cause varying elasticitylevels of the tissue.

Applying the energy may include directing pressurized fluid into the atleast one channel.

The pressurized fluid may include one or more of, for example,pressurized gas, pressurized enhancing fluid to enhance the effect oflaser energy transmitted through the pressurized enhancing fluid, and/orpressurized medicinal fluid.

Directing the pressurized fluid may include directing the pressurizedfluid at a pre-determined time interval following the application ofenergy to form the at least one channel.

The method may further include removing at least some of the fluidoccupying the at least one channel by creating a vacuum externally tothe at least one channel.

Forming the at least one channel may include forming at least onechannel having pre-determined dimensions in the tissue, and a respectivethermally affected thermal zone having a pre-determined configurationprofile, the thermal zone extending away from the at least one channel.

Disclosed herein are apparatus, systems, methods and devices, includingan apparatus for treating tissue that includes a first energyapplication device to direct energy at tissue of a patient to cause atleast one channel to be formed, a second energy application device todirect energy at the tissue of the patient to prevent the at least onechannel from substantially closing, and a controller to controlapplication of energy from the first energy application device to formthe at least one channel, and control application of energy from thesecond energy application device to the at least one channel to preventthe at least one channel from substantially closing for at least apre-determined interval of time. In some embodiments, the second energyapplication device may include a controllable ultrasound device to applyultrasound energy in a direction parallel to a longitudinal axis of theat least one channel to generate standing waves of varying amplitude tocause varying elasticity levels of the tissue. In some embodiments, thesecond energy application device may include a fluid source, and a pumpto provide pressurized fluid from the fluid source towards the at leastone channel.

Hole (or channel) formation in the tissue of a person may be performed,in some embodiments, through microablation procedures by, for example,applying electromagnetic radiation to the tissue for ablating a channeltherein having a (predetermined) width and predetermined depth. In someembodiments, the procedure includes non-ablatively heating tissue on thebottom of the channel with electromagnetic radiation and creating athermal affected zone of predetermined volume proximate said channel.Suitable radiation generating devices that may be used in formingmicrochannels through microablation include, for example, a CO2 laserdevice, an Er:YAG laser device, a Tm:YAG laser device, a Tm fiber laserdevices, an Er fiber laser device, a Ho fiber laser device, and/or othertypes of laser devices. Other types of radiation or energy sources mayalso be used. A schematic diagram of an apparatus to performmicroablation to form microchannels is provided in FIG. 16. Briefly, theapparatus depicted in FIG. 16 may include a laser unit 200 and a laseremitting device 203 for ablating a microchannel 206 into a tissue 205,for example, for applying a treatment thereto. The microchannel 206 maybe, e.g., a column, a well, a hole, or the like, created in the tissue205 by ablating the tissue 205 by the laser emitting device 203 and thelaser beam 204. Microablation of the tissue 205 may result in ablationof the microchannel. Microablation of the tissue may also result indissipation of heat from the heated and evaporated tissue by the tissuesurrounding the resultant microchannel 206. Thus, ablation of the tissue205, producing the microchannel 206, may result in a thermal affectedzone 207 surrounding the walls and/or bottom of the microchannel 206.

In some embodiments, hole stabilization mechanisms may be based on useof an ultrasound device 208 with the laser emitting device 203. Theultrasound generator-208 generates standing waves along the skin'splane, which is perpendicular to the main axis of the holes, in order toelevate the effective Young Modulus of the tissue and make it morerigid. The more rigid the tissue around the holes is, the less it tendsto collapse and block the hole. A standing wave creates “stationary”crests and troughs. The distance between them is proportioned to thewavelength. Assuming a certain holes distribution (distance betweenholes), one can choose a certain wavelength/s that localize/s thesecrests and troughs on the holes or in between the holes. One optionwould be to use a wavelength which is equal to the distance between theholes and to apply the ultrasound in such a relative geometry that thecrests will be in the middle between holes.

Ultrasound energy may be generated, in some embodiments, using anultrasound generator, such as the ultrasound generator 208 depicted inFIG. 16. In some implementations, the generator 208 may be a contactgenerator, in which the generator is mechanically coupled to the tissue(e.g., via a coupling layer such as a suitable fluid couplant), andcauses resultant waves (acoustic waves) through mechanical excitation.Suitable contact-based generators may include, for example, anultrasonic wheel generator (i.e., a movable generator displaced over theobject), an ultrasonic sled generator, and/or a water-coupled generator.These types of generators may include an ultrasonic transducerimplemented, for example, using a piezoelectric element, or some othervibrating transducer, that mechanically oscillates at frequenciescontrollable by regulating the voltage/current applied to thepiezoelectric element. In some implementations, the generator 208 may bea non-contact generator, i.e., the generator is not in direct mechanicalcontact with the object to be inspected. A suitable non-contactgenerator may be an air-coupled transducer that includes a mechanicalvibrating transducer (e.g., such as a piezoelectric element) that cancontrollably oscillate to produce the ultrasonic waves applied to theobject. The output port of such a generator is placed proximate to theobject (e.g., the tissue), and emitted ultrasonic wave are directed tothe object at the application point via an air barrier separating theoutput port of the generator and the object.

Other types and/or implementations of generators to cause waves(ultrasonic waves or other types of waves) may also be used.

In some embodiments, another implementation for hole stabilization is touse using any wavelength with an integer ratio to the distance betweenholes. Such an implementation can be done on symmetric hole pattern(matrix) of statistically on a randomized holes distribution.

In some embodiments, hole stabilization can be achieved by a “pushing”mechanism. Specifically, low amplitude high resolution ultrasound isused today with femtosecond lasers to displace bubbles during thetreatment of human eye lenses. Using ultrasound for transdermal drugdelivery is also known. A similar mechanism may thus be used to pushmaterial through the holes once they are open. This requires anultrasound application (e.g., substantially simultaneously) along thehole's main axis perpendicular to the skin surface.

In some embodiments, application of ultrasound energy may be used tohelp material, like fat, which is ablated at the bottom of the hole, tobe evacuated through the hole (or channel). To perform such materialevacuation, vibrations along the hole's walls are caused. One way to dothat is by changing the amplitude of the standing waves. Under theassumption that a standing wave will change the tissue elasticity, thena “pulsating” elasticity (slightly changed elasticity) will result insmall movements of the hole's wall. This will help the material beingevacuated to travel in either direction, e.g., in and out. If a certainpressure gradient can also be applied by external vacuum, skinstretching, or traveling waves along the hole's wall, then one cancontrol the direction and enhance the evacuation of material from thebottom of the hole.

In some implementations, channel stabilization may be achieved by usinga pressurized fluid, e.g., gas or liquid, to keep open the holes createdby, for example, a CO2 fractional laser in order to allow a second“shot” with the bottom of the hole still open. Such implementationsinclude a mechanism comprising an adapter 300 that fits on the endportion of the laser 302 as illustrated in FIGS. 17A and 17B. In suchimplementations, a vacuum tube 304 with sourced vacuum 306 is attachedto the adapter 300, and a high pressure pump 308 and the 310 coupled tothe adapter (e.g., at its other end) introduce a fluid into the adapter,for example, just prior to activation of the laser. As illustrated inFIG. 17B, tube 304 and 310 which carry vacuum and pressurized fluid(s)may have a plurality of ports within the adapter to allow rapidintroduction and evacuation of fluids. In some embodiments, the fluidcould be a material which enhances the ability of the first laser firingto achieve its desired depth and includes medicinal and/or anestheticsubstances.

In operation, the adapter 300 is placed in contact with the skin 305 asshown in FIG. 17A and pressure applied. A pre-trigger mechanism forcespressure and fluid into the adapter, and then the laser 302 is thenfired. The fluid migrates into the hole 206 waiting for the secondfiring (or other treatment). Then the adapter can be removed or even thevacuum pump activated to remove the fluid into the adapter's tube.Instead of a separate vacuum and pressure source, a single mechanism toperform both functions, such as a reversible pump, may be used. Theforegoing pressurized system may be used instead of the application ofultrasound energy or together with the application of ultrasonic energy.

An additional advantage is that use of the pressure should also serve toreduce pain to the patient. Under the “Gate Theory” of pain management,if the skin is put under pressure (e.g., vacuum or positive pressure onmy part), the brain is tricked into feeling the pressure and not thepain of the holes being drilled into one's skin (this is predicated on aconcept similar to that implemented in the commercially-availableShotBlocker® device which is a pressure plate placed around an injectionsite). When used the pressure on the skin makes the patient “forget”about the injection pain.

Control of Laser Treatment Spots

Referring to FIG. 18, the laser unit of FIG. 1, for example, may deliverthe laser beam in a first predetermined pattern 332 of treatment spotsor in a second predetermined pattern of treatment spots 334.Alternatively, the laser unit may modify the laser beam during thecourse of a single treatment to deliver both the first and the secondpredetermined patterns 332 and 334 of treatment spots producing an areaof overlaid patterns 336 along the surface of the tissue.

The scanner 30 of FIG. 1 and software according to the invention enablesthe laser emitting device 3 of FIG. 1 to deliver a laser beam to thesurface of tissue in one or more predetermined patterns of treatmentspots, as described with reference to FIG. 18, while randomizing thesequence of treatment spots applied to the tissue surface. The treatmentspots are randomized across a given treatment area because of themovement of the scanner, as shown by arrow 40 in FIG. 1, across thetreatment area. While the laser emitting device 3 emits the laser beam,the movement of the scanner across the treatment area in effectrandomizes or “spreads” the predetermined pattern across the treatmentarea. As a result, the density and distribution of the treatment spotsin the given area are random. The scanner 30 may be moved repeatedlyacross the given treatment area such that an overlap of treatment spotsis produced which thereby results in greater spot density anddistribution. In addition, the movement of the scanner 30 permitstreatment of a relatively large treatment area and effectively scans or“brushes” the tissue surface with treatment spots. Repetitive scans orbrushes results in varying densities and distribution of treatment spotsacross the given treatment area that is a function of the number ofbrushes and the overlap between each brush across the treatment area.

Referring to FIG. 19, a facial image illustrates multiple treatmentspots 338 randomly distributed across a treatment area with varying spotdensities at certain areas within the treatment area. As shown in FIG.19, by way of example, the density of treatment spots may be greater inthe middle section of the forehead, an area typically in which wrinklesmay be present. However, density treatment may be varied from that shownin FIG. 19 according to a particular patient's needs. Randomdistribution and varying density of treatment spots 338 results, asmentioned, from the scanner 30 moving across the treatment area todeliver multiple scans or brushes as well as overlaying scans orbrushes. The scanner and software according to the invention therebyenable greater control of treatment spots in terms of distribution anddensity of treatment spots. An operator, such as a physician, maythereby distribute or “spread” treatment spots in a controlled andintuitive manner whereby the operator would scan a particular area ofsurface tissue with greater density, but scan another area with lessdensity, depending upon the tissue and the treatment desired. Forinstance, certain areas may be scanned or brushed repeatedly due todifferent skin characteristics in terms of pigmentation, elasticity,distance to bones, etc. Other areas may receive less treatment and,therefore, have less spot density and/or have a gradual decrease orphasing out of spot density, such as along the boundaries betweentreatment areas and the eyes, lips, and hair.

In one embodiment, instead of the treatment spots being all of eithertype, 6A or 6B as in FIG. 2, the treatment spots may be mixed andmatched so that a user-selectable proportion of 6A type and 6B typetreatment spots are delivered to the patient's skin. For example, thetreatment spots may be a mixture to form a plurality of spots 160 asshown in FIG. 13 and their relative spacing to one another controlled bythe physician.

In addition, the scanner may incorporate speed-sensing ordistance-sensing technology so that the software can deliverpredetermined density of spots to an area of the patient's skin,irrespective of the speed with which the physician moves the scannerover the patient's skin.

Also, under control of the physician, the scanner's software may providetreatment spots like the FIG. 2 type, but in some areas of the patient'sskin only and may provide FIG. 2 type 6B in other areas of the skin,depending on the patient's skin characteristics such as skin elasticity,pigmentation, closeness to hairlines or the eyes, etc.

The foregoing skin treatment is in context to the known “step and shoot”treatment in which the scanner is placed over a spot of skin, then laseractivated and then the scanner is moved to the next adjacent untreatedarea of the patient's skin.

The somewhat random scanning sequences described above may also assistin lowering overall patient pain as the scanner moves when firing thelaser, then spreading the treatment spots of a broader area than withthe traditional “step and shoot” method. The software may program thescanner to disallow two consecutive firings at predetermined distancesfrom one another.

In another embodiment of the invention, the software the scanner 30employs to define the laser beam profile controls the scanning speed orspeed of delivery of the treatment beam with respect to the speed withwhich a physician scans or brushes the treatment area. In one embodimentof the invention, the software correlates the scanning speed to thespeed of the movement that the physician uses to scan or brush thetreatment area. Correlating scan speed and speed of movement of thescanner helps to ensure application of a certain homogeneousdistribution of treatment spots irrespective of the speed the physicianuses to scan or brush the tissue surface.

In another embodiment, the scanner and software according to theinvention are configured to apply two or more predetermined patterns oftreatment spots, such as shown in FIG. 18. As a result, a dynamicdistribution of different treatment spots having different tissueeffects, as can be seen in the depth D of the microchannels 6A and 6B ofFIG. 2, is created in the dermal layer. The software according to theinvention allows selection and control of the different types oftreatment spots or microchannels 6A and 6B. Such selection and controlare achieved with at least the selection and control of the pulse width,the energy fluence, the pulse repetition rate, and any combination ofthese parameters, to create different treatment spots and to enable thescanner to emit laser energy that creates different treatment spots in agiven treatment area. In addition, the software according to theinvention will enable the selection and control of the ratio of two ofmore different treatment spots that are applied to the given treatmentarea.

FIGS. 2 and 18 illustrate two different types of spots or microchannels6A and 6B and two different predetermined patterns of their application.The scanner 30 and software according to the invention may create thesedifferent predetermined patterns in a randomized sequence to produce avarying distribution and density of treatment spots within a treatmentarea. The invention, however, is not limited in this respect andenvisions the software will permit the selection and control of a numberof different types of spots or microchannels and any of a variety ofspot patterns.

The software according to the invention enables the scanner 30 toachieve multi-levels of penetration of the dermal layer. This enables aphysician to tailor and to customize the microablation treatment inaccordance with a patient's skin pathologies and pigmentation and todeliver optimal and highly customized microablation to a singletreatment area.

In a further embodiment of the invention, the scanner 30 and softwareaccording to the invention permits the selection and control ofpredetermined patterns of treatment spots that are not homogenous. Forinstance, a pattern may produce a high density of treatment spots at andproximate to a center of the pattern, while producing a relatively lowdensity of treatment spots at the periphery of the pattern. Combiningcapabilities of selection and control of different non-homogeneoustreatment patterns and their densities and distributions in a giventreatment area, the invention provides a physician with an ability totreat different skin characteristics simultaneously, a capability tovary depths of ablation, and a technique to accommodate the boundariesbetween treatment and non-treatment areas, such as eyes, lips, and hair.The software in effect allows repeated scanning or brushing, whileapplying precisely required or desired treatment spot densities.

Description of Foot Activated Control

Referring to FIG. 20, in one aspect, the invention provides afoot-activated control (entitled herein a footswitch) 410 that isconstructed and arranged for use in controlling and, more particularly,in actuating a light-based system or device. The footswitch 410 includesat least one electrical cable 413 to couple the footswitch 410operatively to the light-based system or device. Such light-based systemor device is configured for emission of laser and/or other coherentlight applied in accordance with ablation methods to the surface oftissue for various treatments.

The footswitch 410 includes a pedal 412 having, in one configuration, asubstantially planar surface and sufficient area 412A to receive atleast a portion of an operator's foot. The pedal 412 is actuated oractivated, e.g., depressed, by the operator's foot on the surface 412A.In this manner, the footswitch 410 serves as an accelerator to increaseor to decrease the firing of the light-based system or device, suchthat, the system or device increases or decreases, e.g., the durationof, the emission ablation treatment radiation. For example, thefootswitch 410 may be useful in connection with controlling the densityand depth of treatment spots 338 in FIG. 19.

In one configuration of the invention, the footswitch 410 is constructedand arranged as a “smart” pedal 412 that provides a dynamic range ofcontrol of one or more parameters of the tissue ablation treatment,including, but not limited to, repetition rate, light energy, lightpenetration, light depth, treatment spot size, spot density, repetitionrate, etc. Each parameter may be associated with a sensor 414A, 414B,414C, and 414D that is integrated with the footswitch 410 and, forinstance, is disposed below an outer sheath covering the surface 412A ofthe pedal 412 (as shown in dashed lines in FIG. 20). The operator maythereby control dynamically, during treatment, one or more parameters byactuating with their foot one or more sensors 414A, 414B, 414C, and414D, alone or in any combination. FIG. 20 shows four sensors and aparticular arrangement of the sensors 414A, 414B, 414C, and 414D on thepedal 412. The invention, however, is not limited in this respect andenvisions that any number of sensors may be incorporated with the pedal12 and in any of a variety of configurations and arrangements.

Referring to FIG. 21 and with further reference to FIG. 20, thefootswitch 410 may be operatively coupled with a user interface 416 thatenables the operator to select various modes of operation of andparameters for actuation by the footswitch 410. The interface 416 mayinclude a visual display 417 of the modes 417A and the parameters 417Bthat the footswitch 410 may control. Such modes and parameters 417A and417B may be selected and activated for control by the footswitch 410 by,for instance, touch-screen software. In one configuration, the interface416 may be incorporated with the light-based system or device to whichthe footswitch 410 is coupled operatively. Alternatively, oradditionally, the interface 416 may be a peripheral device that isconfigured to operate alone or in conjunction with a controller, whichis operatively coupled with the light-based system or device.

The invention further includes any software, hardware, and firmware, andassociated electronics, that are required to operate and to providecontrol of the footswitch 410, the sensors 414A, 414B, 414C, and 414D,and the interface 16, and that are required to integrate the footswitch10 and the interface 16 with a light-based system or device and/or acontroller.

Having thus described at least one illustrative aspect of the invention,various alterations, modifications and improvements will readily occurto those skilled in the art. Such alterations, modifications andimprovements are intended to be within the scope and spirit of theinvention. Accordingly, the foregoing description is by way of exampleonly and is not intended as limiting. The invention's limit is definedonly in the following claims and the equivalents thereto.

What is claimed is:
 1. A method of treating human skin tissue,comprising: providing a first energy application device that isconfigured to direct energy at selected positions on the skin tissuesurface of a patient to cause to be formed a plurality ofvertically-disposed channels of a given depth and width in the skintissue surface; providing a controller configured to control applicationof energy from the first energy application device to form the pluralityof channels; the method comprising: the controller being operated tocause the first energy application device to form a plurality ofchannels at a plurality of selected positions on the selected skinsurface of a patient, the density of the distribution of the pluralityof channels being non-uniformly distributed over the surface of the skintissue, and; wherein the plurality of channels formed by the energyapplication device under control of the controller are made to be ofvarying depth of penetration into the skin surface, the depth beingcontrolled by the controller in response to sensing the position of thefirst energy application device on the skin surface by a sensor devicemounted on the first energy application device.
 2. The method of claim1, further comprising the step of moving the first energy applicationdevice over the skin surface, wherein a time rate of the first energyapplication device forming the plurality of channels is determined by arate of travel of the first energy application device over the skinsurface.
 3. The method of claim 2, wherein the sensor device is mountedon the first energy application device and is operatively connected tothe controller, wherein the sensor device senses the rate of travel ofthe first energy application device over the human skin surface andsignals the controller to cause the first energy application device toform the plurality of channels.
 4. The method of claim 1, wherein thecontroller is operatively connected to one of a manually orfoot-operated device, the manually or foot-operated device being engagedand controlling the application of the first energy application device.5. The method of claim 1, wherein the controller includes a manual orfoot-operated device, the device being engaged to apply energy to theselected positions on the skin tissue surface with a selected randomlydetermined density.
 6. A method of treating human skin tissue,comprising: providing a first energy application device that isconfigured to direct energy at selected positions on the skin tissuesurface of a patient to cause to be formed a plurality ofvertically-disposed channels of a given depth and width in the skintissue surface; providing a controller configured to control applicationof energy from the first energy application device to form the pluralityof channels; the method comprising: the controller being operated tocause the first energy application device to form a plurality ofchannels at a plurality of selected positions on the selected skinsurface of a patient, the density of the distribution of the pluralityof channels being non-uniformly distributed over the surface of the skintissue, and; wherein the plurality of channels formed by the energyapplication device under control of the controller are made to be ofvarying depth into the skin surface, the depth being controlled by thecontroller in response to sensing the position of the first energyapplication device on the skin surface by a sensor device mounted on thefirst energy application device, wherein the density of the plurality ofchannels formed on the skin surface are controlled by the controller inresponse to sensing the position of the first energy application deviceson the skin surface by the sensor device operatively associated withinthe first energy application device.
 7. The method of claim 6, whereinthe density of the plurality of channels on the skin surface arecontrolled by the controller in response to sensing of one or more of:pigmentation of the skin tissue, elasticity of the skin tissue, distancefrom the skin tissue surface to bone structure, and proximity to apatient's eyes, lips and hair.
 8. The method of claim 7, wherein thedensity of the plurality of channels is less dense around a patient'seyes, lips or hair than at the remainder of a patient's face.
 9. Themethod of claim 6, wherein the controller in addition causes theplurality of channels to be formed with different widths.
 10. A methodof treating human skin tissue, comprising: providing a first energyapplication device that is configured to direct energy at selectedpositions on the skin tissue surface of a patient to cause to be formeda plurality of vertically-disposed channels of a given depth and widthin the skin tissue surface; providing a controller configured to controlapplication of energy from the first energy application device to formthe plurality of channels; the method comprising: the controller beingoperated to cause the first energy application device to form aplurality of channels at a plurality of selected positions on theselected skin surface of a patient, the density of the distribution ofthe plurality of channels being non-uniformly distributed over thesurface of the skin tissue, and; wherein the plurality of channelsformed by the energy application device under control of the controllerare made to be of varying depth into the skin surface, the depth beingcontrolled by the controller in response to sensing the position of thefirst energy application device on the skin surface by a sensor devicemounted on the first energy application device; wherein the controlleris operatively connected to one of a manually or foot-operated device,the manually or foot-operated device being engaged and controlling theapplication of the first energy application device; wherein thefoot-operated device includes foot-activatable devices to control one ormore of the parameters: time intervals between activation of the firstenergy application device; an amount of energy delivered to the firstenergy application device; the given depth of the plurality of channelsformed; the distribution of the plurality of channels formed on the skinsurface; and the given width of the plurality of channels formed;wherein each parameter is controlled by a separate sensor device mountedon the foot-operated device.
 11. The method of claim 10, wherein atleast one of the separate sensor devices controlling the parameters isvariably activatable.